Adjustable flow control elements for balancing pulverized coal flow at coal pipe splitter junctions

ABSTRACT

An adjustable device installed at the inlet of conventional junctions/splitters ( 116 ) for on-line control of the distribution of coal among the outlet pipes is herein disclosed. The device includes a plurality of flow control elements ( 60 ) each positioned upstream of a plurality of flow channels in the riffler ( 50 ) for directing coal flow to the outlet pipes. Each flow control element preferably comprises a rounded convex edge leading to straight tapered sides (FIG.  9 ). The surfaces of the sides may be roughened or textured ( 63 ) for promoting turbulent boundary layers (FIG.  9 ). In addition, conventional fixed or variable orifices may be used in combination with the flow control elements for balancing primary air flow rates. The device allows fine-adjustment control of coal flow rates when used in combination with the slotted riffler, yet it has negligible effect on the distribution of primary air. The combination of the riffler assembly and the coal flow control elements ( 60 ) results in closely balanced coal flow. Balanced coal flow is imperative to the optimization of the operation of pulverized coal boiler systems (i.e. reduced pollutant emissions, improved combustion efficiency).

This application claims the benefit of provisional application 60/199,300 filed Apr. 24, 2000 and 60/265,206 filed Feb. 1, 2001.

TECHNICAL FIELD

The invention relates to pulverized coal boiler systems and, more particularly, to riffler assembly and flow control element (e.g. adjustable air foil) designs for balancing the flows of pulverized coal therein.

BACKGROUND ART

In a typical large pulverized coal boiler, coal particulate and primary air flow from the pulverizers to the burners through a network of fuel lines that are referred to as coal pipes.

FIG. 1 illustrates a typical large pulverized coal boiler inclusive of pulverizer(s) 10, furnace 30, and network of coal pipes 20. For proper operation of the boiler, all the coal pipes 20 connected to any one of the pulverizers 10 should carry the same coal flow rates and the same flow rates of primary air.

Unfortunately, differences in coal and primary air flow rates from one coal pipe 20 to the next are a limiting factor in the ability to reduce NO_(X) emissions in pulverized coal boilers. High carbon monoxide emissions and high levels of unburned carbon can result from burner imbalances. High fly ash unburned carbon, in turn, can adversely affect electrostatic precipitator collection efficiency and result in elevated stack particulate emission levels. Imbalances in coal pipe flows can also lead to maintenance problems associated with coal pipe erosion and/or clogging (e.g. excessive localized coal accumulation), damage to burners and windboxes, and accelerated waterwall wastage. Problems such as these reduce the operating flexibility of the boiler and often require that the boiler be operated under conditions which produce higher NO_(X) levels than would otherwise be achieved.

The distribution of primary air throughout the coal piping network is controlled by the flow resistances of the various coal pipes 20. Because of differences in pipe lengths and numbers and types of elbows in each fuel line, the different coal pipes from a pulverizer will usually have different flow resistances. It is known that orifices or flow restrictors can be installed within the pipes 20 for use in adjusting the individual primary air flows to make them equal.

For example, U.S. Pat. No. 5,593,131 to O. Briggs and J. Sund shows a Variable Orifice Plate for Coal Pipes for balancing coal pipe flows.

U.S. Pat. No. 5,685,240 to O. Briggs and J. Sund shows a Variable Orifice Plate for Coal Pipes.

U.S. Pat. No. 4,094,492 to R. Beeman and S. Brajkovich shows a Variable Orifice Using an Iris Shutter.

U.S. Pat. No. 4,779,546 to W. Walsh shows a Fuel Line Orifice.

U.S. Pat. No. 5,975,141 to M. Higazy shows an On-Line Variable Orifice.

U.S. Pat. No. 4,459,922 to R. Chadshay shows an Externally Adjustable Pipe Orifice Assembly.

It can be seen in the above-cited references that orifices with both fixed geometry and adjustable geometry are available commercially.

While the use of fixed or adjustable orifices can be an effective way of balancing primary air flow rates, evidence from field and laboratory measurements indicates the orifices have little effect on coal flow rates. Instead, the coal flow distribution among the pipes is affected most strongly by flow conditions and geometry in the inlet regions of the pipes.

FIG. 2 illustrates a coal pipe 20 according to one piping arrangement commonly encountered in pulverized coal boiler systems. This arrangement involves coal and primary air flow from one pipe 20 dividing into two flows at a Y-shaped junction/splitter. Industry-wide experience shows the coal flow rates among the two outlet pipes 22, 23 can be severely imbalanced. More specifically, conventional orifices 40 a-b are installed to prevent primary air flow imbalance and the underlying table shows the results from a series of laboratory tests carried out on the effectiveness of orifices 40 a-b. As the data show, selection of the proper orifices 40 a-b as required to balance the primary air flow rates did not simultaneously result in a balanced coal flow distribution. In fact, in this case, the orifices 40 a-b increased the coal flow imbalance from 9.45% to 18.4%.

Another attempted solution for the coal flow imbalance is the use of adjustable baffles to modify the coal flow distribution among the outlet pipes 22, 23. The following references describe the use of baffles to modify coal flow distribution.

U.S. Pat. No. 4,570,549 to N. Trozzi shows a Splitter for Use with a Coal-Fired Furnace Utilizing a Low Load Burner.

U.S. Pat. No. 4,478,157 to R. Musto shows a Mill Recirculation System.

U.S. Pat. No. 4,412,496 to N. Trozzi shows a Combustion System and Method for a Coal-Fired Furnace Utilizing a Low Load Coal Burner.

In all of the above-described designs, the baffle is located upstream of the Y-junction and is used to control the relative amounts of coal flowing through the two outlet pipes 22, 23. This use of adjustable baffles can be an effective way of modifying the distribution of the coal flow because the baffles can be adjusted to various positions. However, adjustment of the baffles also simultaneously causes unacceptably large changes in primary air flow distribution. As a consequence, it is very difficult with an adjustable baffle approach to simultaneously balance coal and primary air flow rates.

A third alternative comprises the insertion of a slotted riffler in a splitter box as shown in FIG. 3 (prior art). The slotted riffler configuration is also commercially used to reduce fuel flow imbalances. The slotted riffler concept consists of a series of flow channels with rectangular cross sections, each of which directs a portion of the coal and primary air flow to one of the outlet pipes. Field measurements show that while these types of rifflers can help to reduce coal flow imbalance arising from a mal-distribution of coal flow at the inlet, they generally do not eliminate the imbalance. Additional fine control of the coal flow distribution is still needed.

Often, due to the configuration of the boiler system, the flow from a single coal pipe must be split into more than two flows. FIG. 4 shows an example of a four-way splitter arrangement 100 that is sometimes encountered in pulverized coal boiler systems. The arrangement 100 involves coal and primary air flow from a single pipe 102 dividing into four flows at a four-way splitter 104. Industry experience shows that the coal flow rates among the four outlet pipes 106 a-d can be severely imbalanced. This is because the distribution of coal flow rates among the pipes 106 a-d strongly depends on the pulverized coal flow distribution at the inlet cross-section of the four-way splitter 104, and a significant pulverized coal flow non-uniformity exists due to an upstream elbow 110. The non-uniformity causes the coal particles to stratify into a narrow localized stream (i.e. rope flow) close to the outer wall of the elbow 110. For this reason, a flow splitter must be installed either sufficiently far from an elbow or be designed to accommodate significant coal flow non-uniformity. However, due to the space limitations associated with many applications/installations, a flow splitter has to be installed immediately after an elbow where, as stated above, the coal particulate exists as a narrow, localized rope flow.

FIG. 5 shows a sub-section of a known existing installation where a Venturi 112 was installed between the exit of the elbow 114 and the inlet of the four-way splitter 116 in an attempt to lower inherent coal flow imbalances. Laboratory testing with this configuration showed a ±35% coal flow imbalance among the four outlet pipes 118.

In the foregoing and all other known designs, the Venturi/restrictor(s) are fixed. The use of adjustable baffles would be a more effective way of modifying the distribution of the coal flow because the baffles can be adjusted to various positions. However, adjustment of baffles would also simultaneously cause unacceptably large changes in primary air flow distribution. As a consequence, it is very difficult with an adjustable baffle approach to simultaneously balance coal and primary air flow rates.

It would, therefore, be advantageous to provide splitter designs that eliminate coal flow imbalances at crucial points in a pulverized coal boiler system using an on-line adjustment capability (i.e. while the pulverized coal boiler system is in operation). This would permit the operation of the pulverized coal boiler system to be optimized and result in reduced pollutant emissions and improved combustion efficiency.

DISCLOSURE OF INVENTION

It is, therefore, the main object of the present invention to provide an improved method and apparatus for the on-line balancing of multiple coal flows in a pulverized coal boiler system using a slotted riffler configuration, thereby making it possible to operate the boiler system with reduced pollutant levels (e.g. NO_(x), CO) and increased combustion efficiencies.

It is another object of the present invention to provide an improved method and apparatus for the on-line balancing of multiple coal flows in a pulverized coal boiler system that does not disturb any pre-existing primary air flow balance among the multiple coal pipes.

It is a further object of the present invention to provide an improved method and apparatus for the on-line balancing of multiple coal flows in a pulverized coal boiler system at any of a two-way, three-way, and four-way splitter respectively having four outlet pipes.

It is a further object of the present invention to provide an improved method and apparatus for the on-line balancing of multiple coal flows in a pulverized coal boiler system that can be readily installed within the piping networks of existing pulverized coal power plants.

The above objects will become more readily apparent on an examination of the following description and figures. In general, the present invention disclosed herein includes a new method and apparatus for coal flow control at junctions/splitters common to some pulverized coal transfer systems at coal-fired power plants.

The present invention includes riffler assemblies designed to lower coal flow imbalance (i.e. restore uniform particulate flow distribution). Furthermore, the present invention includes flow control elements (e.g. a plurality of air foils) located just upstream of the riffler assembly to provide means for on-line coal flow adjustment/control. Each flow control element preferably comprises a rounded, convex edge leading to straight tapered sides (the side surfaces may be roughened or textured to promote turbulent boundary layers). The combination of the riffler assembly and the flow control elements, making it possible to achieve on-line control of the flow distribution, results in closely balanced coal flow in the outlet pipes.

BRIEF DESCRIPTION OF DRAWINGS

Other objects, features, and advantages of the present invention will become more apparent from the following detailed description of the preferred embodiment and certain modifications thereof when taken together with the accompanying drawings in which:

FIG. 1 illustrates a typical large pulverized coal boiler inclusive of pulverizer(s) 10, furnace 30, and network of coal pipes 20.

FIG. 2 illustrates a coal pipe 20 according to one typical piping arrangement commonly encountered in pulverized coal boilers.

FIG. 3 illustrates a prior art slotted riffler in a splitter box.

FIG. 4 illustrates a multi-pipe arrangement 100 that is sometimes encountered in pulverized coal boiler systems.

FIG. 5 illustrates a sub-section of a multi-pipe arrangement where a Venturi 112 has been installed.

FIG. 6 shows an array of long air foil-like flow control elements 60, according to a first embodiment of the present invention, that are placed just upstream of the inlet to a conventional riffler 50.

FIG. 7 illustrates the discrete riffler 50 channels (indicated left “L” and right “R”) with a pair of upstream flow control elements 60 a and 60 b according to a first embodiment of the present invention.

FIG. 8 illustrates the transverse displacement of flow control elements 60 a and 60 b to increase coal flow to the left side of the riffler 50.

FIG. 9 is a cross-section of the preferred shape of a single flow control element 60 according to a first embodiment of the present invention.

FIG. 10 illustrates the width of the wake in the primary air flow downstream of flow control element 60.

FIG. 11 shows the addition of roughness elements 63 for further reducing the width of the primary air wake (Wa).

FIG. 12 illustrates three examples of alternative flow control element shapes, each of which creates primary air and particle wakes having certain widths and other characteristics.

FIG. 13 is a plot of the particle trajectories downstream of flow control element 60.

FIG. 14 is a graphical illustration of the particle concentration wake (A) and primary air flow wake (B) which result from the above-referenced flow control element 60 design.

FIG. 15 is a plot showing the effect of the lateral position Δy of the flow control elements 60 on the coal and primary air flow imbalances.

FIG. 16 shows a single four-way riffler element assembly 120 according to an alternative embodiment of the present invention.

FIG. 17 shows the joining of two, four-way riffler element assemblies 120 to form a sub-section of a complete four-way splitter.

FIGS. 18 and 19 are a perspective view and a top view, respectively, showing a complete four-way splitter 140 with four riffler element assemblies 120 joined as in FIG. 17.

FIGS. 20, 21 and 22 are a top view, side view and front view, respectively, of a square outlet coal pipe arrangement, utilized in pulverized coal boiler systems, that require the use of four-way splitters.

FIGS. 23-26 are a top view, end view, front view, and bottom view of an in-line outlet coal pipe arrangement.

FIG. 27 is an end view perspective of the complete four-way splitter 140, including the first and second stage flow control elements 122, 124, according to an alternative embodiment of the present invention.

FIG. 28 is a graphical representation of the results of a series of laboratory tests on the effect of the position of the first stage flow control element 122 on the coal flow balance within a four-way splitter 140 designed in accordance with an alternative embodiment of the present invention.

FIG. 29 is a graphical representation of the results of a series of laboratory tests showing the coal flow balancing capability of a four-way splitter 140 designed in accordance with an alternative embodiment of the present invention.

FIG. 30 is a graphical representation of the results of a series of laboratory tests demonstrating the effect of the position of the first and second stage flow control elements 122, 124 on the pre-existing primary air flow balance within a four-way splitter 140 designed in accordance with an alternative embodiment of the present invention.

BEST MODE(S) FOR CARRYING OUT THE INVENTION

As described above, the distribution of primary air in most coal boilers must be controlled separately by use of orifice-type restrictions in individual pipes. It is important for good combustion that the mechanism for controlling the coal flow distribution have negligible effect on the distribution of primary air. The present invention offers a solution in the form of adjustable flow control elements installed at the inlet of a slotted riffler, for on-line control of the distribution of coal among the outlet pipes. The flow control elements create primary air and particle wakes, and the distribution of pulverized coal and primary air to the coal boiler can be manipulated by controlling the location, size and characteristics of the wakes via the flow control elements.

More specifically, and as shown in FIG. 6, one embodiment of the present invention consists of an array of long air foil-like flow control elements 60 that are placed just upstream of the inlet to a conventional riffler 50. As described above, a conventional riffler 50 (see FIG. 3) when used in a two-way splitter (see FIG. 2) directs the flow of primary air to either the left or right outlet pipe by alternate riffler flow channels. When flow control elements 60 are placed upstream of riffler 50 and directly in-line with the internal walls of the riffler 50, the elements 60 have no effect on the coal flow distribution through the riffler 50. However, lateral movement of flow control elements 60 causes a shift in the coal flow distribution through the riffler 50.

FIG. 7 illustrates the discrete riffler 50 channels (indicated as left “L” and right “R”) with a pair of upstream flow control elements 60 a and 60 b positioned in-line with the internal walls of the riffler 50. When the flow control elements 60 a and 60 b are moved sideways, either to the right or left, they cause a shift in the coal flow distribution through the riffler 50.

More specifically, FIG. 8 illustrates the selective right-displacement of flow control elements 60 a and 60 b to increase coal flow to the left side of the riffler 50. Increasing amounts of displacement Δy will cause an increase in coal flow to the left outlet pipe L and a corresponding decrease in coal flow to the right outlet pipe R.

An entire array of parallel flow-control elements 60 can be adjustably mounted on positioning rods (not shown) supported by bushings in the outer walls of the piping system. This way, the selective transverse position Δy of all parallel flow-control elements 60 can be simultaneously adjusted from outside the pipe by sliding the positioning rods, in or out of the pipe, thereby permitting on-line control of the coal flow distribution.

The individual flow control elements 60 preferably employ a particular streamlined shape to ensure that the control of coal flow distribution does not affect the primary air flow distribution. For best performance, each element 60 preferably has a tear-drop shape similar to that shown in FIG. 9. The breadth b of upstream surface of element 60 is convex, with a circular or nearly-circular profile. The straight sides of the element are tapered along their length at an angle .alpha. to an apex. The primary air flow creates boundary layers on the surfaces of the element 60, thereby producing a wake region downstream. All of the physical dimensions of the flow control element 60 combine to affect the nature of the wake.

FIG. 10 illustrates the width of the wake in primary air flow downstream of element 60. With combined reference to FIGS. 9 and 10, the dimensions of the element 60 and magnitude of the average primary air velocity in the coal pipe result in laminar boundary layers on the sidewalls of the element 60. Laminar boundary layers are particularly susceptible to boundary layer separation for a sufficiently large angle α. Delaying the onset of separation to positions further downstream (larger x) reduces the width of the wake region (Wa) for the primary air flow. This reduces the effect of changes in position of the control element 60 on primary air flow distribution through the riffler 50.

The further addition of surface roughness on the tapered side surfaces of the elements 60 can trigger transition to turbulence. This moves the flow separation even further downstream and reduces the width of the primary air wake (Wa) even more

FIG. 11 shows the addition of roughness elements 63 for further reducing the width of the primary air wake (Wa). Roughness elements 63 may be any suitable sputter-coating on flow control element 60, or machined ribs, grooves or the like. The roughness elements and/or other surface textures reduce the width of the primary air wake (Wa) by delaying flow separation.

It should be understood that flow control element shapes other than as indicated in FIGS. 6-11, and other element surface contours/textures can be used, depending on the application. The goal is the creation and control of a wake region. Other shapes create wakes having different sizes and characteristics. Consequently, certain other shapes may be well suited for certain other purposes. For example, FIG. 12 illustrates three examples of alternative flow control element shapes: a blunt leading edge (top); a wedge leading edge (middle); and curved surfaces (bottom). Each of the alternative shapes of FIG. 12 create primary air and particle wakes having certain widths and other characteristics.

FIG. 13 is a plot of the coal particle trajectories downstream of flow control element 60. As seen in FIG. 13, the width of the particle wake (Wp) is controlled by the particle size distribution, the velocity of upstream flow, the width b (as in FIG. 9) of element 60, and the shape of the upstream surface of the element 60. The rounded, convex shape of flow control element 60 is presently preferred because it provides a smooth match with the straight tapered side walls of the coal pipe 20. The width b of element 60 is limited by the widths of the flow channels in riffler 50. For the typical particle sizes and flow velocities which occur in coal pipes in pulverized coal boilers, the width of the particle wake is larger in magnitude than the width b of element 60 as shown in FIG. 9.

FIG. 14 is a graphical illustration of the particle concentration wake (A) and primary air flow wake (B) which result from the above-referenced flow control element 60 design. It can be seen that the particle wake causes a bell-curve reduction in particle flow across a width Wp that exceeds the width b of the flow control element 60. On the other hand, the primary air flow wake causes only a minor interruption in primary air flow across a width Wa that is smaller than the width b of the flow control element 60. Thus, the elements 60 have a negligible effect on the distribution of primary air and this eliminates the need for separate control of orifice-type restrictions in individual pipes.

Laboratory tests have been conducted which demonstrate the effectiveness of the above-described invention in controlling coal flow distribution, without affecting primary air flow distribution. These tests were carried out with a 6″ inlet pipe and two 4″ outlet pipes. The inlet air velocity was 100 feet per second (fps) and the ratio of the mass flow rate of pulverized coal to the mass flow rate of air was 0.7.

FIG. 15 is a plot of test results showing the effect of the lateral position Δy of the flow control elements 60 on the coal and primary air flow imbalances. The data show small adjustments in flow control element position Δy resulted in large changes in coal flow distribution, but almost no change in primary air flow distribution.

Other common configurations found in coal boiler systems split the flow of coal/primary air from one inlet pipe into three or four outlet pipes by use of a riffler assembly. The same above-described approach of adjustable air foil elements if used in combination with a slotted riffler can be applied in these cases to control the distribution of coal flow among the outlet pipes.

FIG. 16 shows a single four-way riffler element assembly 120 that splits the flow of coal/primary air into four outlet flow channels 128. The riffler element assembly 120 of FIG. 16 incorporates a flow control assembly with two stages of flow control elements 122, 124 according to an alternative embodiment of the present invention. In the illustrated embodiment, the four-way riffler element assembly 120 includes an inlet flow channel 125 (not shown in FIG. 16, see FIG. 21) for creating flow as shown by directional arrow 126, two intermediate flow channels 127, and four outlet flow channels 128. The two-stage flow control assembly includes a first stage flow control element 122 and two second stage flow control elements 124. Each of the three flow control elements 122, 124 is adjustable sideways from a ‘neutral’ position (aligned with the wall of its corresponding channel). All flow control elements in each respective stage 122 and 124 may be adjusted in tandem by mounting rods as will be described. The coal/primary air mixture flows through the inlet channel 125 and around the first stage flow control element 122. The element 122 distributes the coal/primary air mixture into the intermediate flow channels 127 where it flows around the second stage flow control elements 124. These elements 124 further distribute the mixture into the outlet flow channels 128.

FIG. 17 shows the side-by-side joining of two, four-way riffler element assemblies 120 as in FIG. 16 plus a respective pair of two-stage flow control assemblies both including a first stage flow control element 122 and two second stage flow control elements 124, to thereby form a complete four-way splitter.

FIGS. 18 and 19 are a perspective view and a top view, respectively, showing a complete four-way splitter 140 including the housing 142 and four riffler element assemblies 120 joined as in FIG. 17.

FIGS. 20, 21 and 22 are a top view, side view and front view, respectively, of another example of a square outlet coal pipe arrangement, utilized in pulverized coal boiler systems, that require the use of four-way splitters.

FIGS. 23-26 are a top view, end view, front view, and bottom view of an in-line arrangement. Factors such as the pre-existing layout of the coal/primary air mixture delivery system dictate which of the possible outlet pipe arrangements can be implemented.

FIG. 27 shows the relative positions of the first and second stage flow control elements 122, 124, respective mounting rods 131, 132 for tandem adjustment, and the inlet, intermediate, and outlet flow channels 125, 127, 128. It can be readily seen how the present invention achieves coal flow control in a two stage process. Flow from the inlet flow channel 125 is passed by the first stage flow control element 122 in order to convert the single flow into two, approximately equal coal flows through the two intermediate flow channels 127. Generally, the two intermediate flows are each then passed by the second stage control elements 124 in order to convert the two intermediate flows into four, approximately equal coal flows, which are in turn directed into each of four discrete channels of a riffler element assembly to accomplish balanced coal flows among all outlet pipes thereof. Moreover, the apparatus for the on-line balancing is simple in construction, contains a small number of individual components, and can be provided as original equipment or designed to readily retrofit a large number of existing pulverized coal boiler systems without excessive modification.

More specifically, the first stage flow control elements 122 (attached to mounting rod 131) are for balancing coal flows in the intermediate channels 127 (those designated “M” and “N”). The second stage flow control elements 124 (two sets that are independently adjustable via two sets of mounting rods 132) are for balancing coal flows in the outlet pipes 128. The positions of the flow control elements 122, 124 with respect to each other (i.e. along the mounting rods 131, 132), and the distance from them to the leading edges of the flow channel walls (shown as dimensions “D1” and “D2”) are selected so as not to disturb the primary air flow balance in any of the outlet pipes 128 as the position of the flow controller elements 122, 124 are adjusted by sliding the mounting rods 131, 132 to the left or right (as oriented in FIG. 23).

The mounting rods 131, 132 are accessible during any normal operating cycle of the pulverized coal boiler assembly. This provides for the opportunity to make “on-line” adjustments to the positions of the first and second stage flow control elements 122, 124 during normal operation of the boiler system. On-line adjustments allow the operation of the boiler system to be optimized independently of other surrounding conditions.

Referring back to FIG. 9, the preferred cross-section of the flow control elements 122, 124 as in FIGS. 17 and 27 is likewise cone-shaped with a convex, rounded leading surface possessing a width “b” that is proportional to the width of the flow channel in which it is positioned. Downstream of the flow control elements 122, 124, the coal flow creates a wider wake than that of the primary air flow. In other words, the primary air flow is only slightly affected by the streamlined design of the flow control elements 122, 124. Laboratory tests have demonstrated the effectiveness of the foregoing device in adjusting coal flow distribution without affecting primary air flow distribution. Tests were carried out with a single 6″ inlet pipe and four 3¼″ outlet pipes. The inlet air velocity was set at 75 feet per second (fps) and the ratio of the primary air mass flow rate to the coal mass flow rate was 1.7. The amount of flow imbalance is defined as the flow rate differential between the measured flow in a pipe and the average flow rate that would create perfectly balanced flow among the four outlet pipes, divided by that same average flow rate. Therefore, the amount of flow imbalance at a four-way splitter can be mathematically expressed as: $I_{i} = \frac{m_{i} - m_{avg}}{m_{avg}}$

Where the term m_(i) represents the measured flow rate in the i^(th) outlet pipe and the term m_(avg) is the average flow rate calculated as follows: $m_{avg} = \frac{m_{1} + m_{2} + m_{3} + m_{4}}{4}$

FIG. 28 plots the effect of the position of the first stage flow control elements 122 on coal flow balance between the intermediate channels 127 designated (in FIG. 27) with an “M” and those marked with an “N”. As the first stage flow control elements 122 were moved towards the left (as seen in FIG. 27), less coal flowed to the “M” channels, resulting in negative coal flow imbalances for the “M” channels (as shown by the solid line in FIG. 28). In a similar fashion, as the first stage flow control elements 122 were moved towards the right, less coal flowed to the “N” channels, resulting in negative coal flow imbalances for the “N”channels (as shown by the dotted line in FIG. 28). With the flow control elements 122 positioned 0.04″ to the right of the neutral position shown in FIG. 27, the coal flows to all of the intermediate channels 127 were perfectly balanced.

It should be mentioned that this 0.04″ from neutral position for the first stage elements 122 does not guarantee balanced coal flow between the various outlet pipes 128 designated (in FIG. 27) with “1”, “2”, “3”, and “4”. To accomplish balanced coal flows among all outlet pipes 128, the second stage flow control elements 124 must also be positioned properly.

The results of several laboratory trials are illustrated in FIG. 29. Test no. 1 shows the coal flow imbalance for the four outlet pipes using the four-way splitter configuration shown in FIG. 5 (i.e. without four-way riffler element assemblies and flow control elements). Test no. 2 shows the results obtained by using the present invention with the flow control elements 122, 124 located at the neutral positions shown in FIG. 27 (i.e. aligned with the walls of the intermediate and outlet flow channels). A comparison of Test nos. 1 and 2 indicates that the coal flow imbalance was reduced from ±35% to ±13% by using the new four-way splitter. A series of changes in the positions of the flow control elements 122, 124 are reflected in the results of Test nos. 3 through 6. Note that Test no. 6 shows nearly perfect coal flow balance among the four outlet pipes, a reduction in coal flow imbalance to less than ±4%.

FIG. 30 plots the primary air flow imbalance present during each of the last five coal flow tests recorded in FIG. 29 (i.e. Test nos. 2 through 6). As is readily apparent from the five sets of data shown in FIG. 30, any change in the positions of the flow control elements 122, 124 has only a slight effect on the pre-existing primary air flow imbalance.

It is noteworthy that in some piping arrangements, the coal/primary air flow from a single pipe is split into three, four, five or more outlet streams. It should be understood that the present invention encompasses system configurations in addition to those described above (for two or four outlet pipes), for instance, which combine adjustable flow control elements with a slotted riffler utilized to control the distribution of coal flow among three outlet pipes, five outlet pipes or any number of outlet pipes.

INDUSTRIAL APPLICABILITY

Typical pulverized coal boiler systems have internal imbalances due to upstream obstructions (e.g. one or more elbows). Thus, the pulverized coal flow at the inlet of a conventional two- or four-way junction/splitter possesses a non-uniform distribution. Prior art junctions/splitters typically utilize orifices, adjustable baffles or riffler assemblies to reduce the effects of inlet flow non-uniformity on the overall coal flow balance. Unfortunately, these conventional approaches generally do not eliminate imbalances. There would be great commercial advantage in a device that substantially eliminates imbalances, and such a device is herein disclosed in the context of two- and four-way riffler assemblies designed to lower coal flow imbalance (i.e. restore uniform particulate flow distribution). Furthermore, there would be great commercial advantage in a device that provides control over imbalances, and the present invention further includes flow control elements (e.g. a plurality of air foils) located just upstream of the riffler assembly to provide means for on-line coal flow adjustment/control. The combination of the riffler assembly and the flow control elements makes it possible to achieve on-line control of the flow distribution, thus resulting in closely balanced coal flow in the outlet pipes. 

What is claimed is:
 1. A method of balancing coal flow, without disturbing an existing primary air flow, in pulverized coal boiler systems with splitter junctions having a single inlet coal pipe and a plurality of outlet coal pipes, comprising the steps of: passing a combined coal/primary air flow over a plurality of first stage flow control elements in order to convert said combined flow into a plurality of approximately equal coal/primary air flows; directing each of said plurality of approximately equal coal/primary air flows preferentially into a plurality of first stage discrete channels of a riffler assembly; passing the plurality of approximately equal coal/primary air flows over a plurality of second stage flow control elements located within said plurality of first discrete channels in order to convert said plurality of approximately equal second stage coal/primary air flows into a plurality of approximately equal third stage coal/primary flows; directing each of said plurality of approximately equal third stage coal/primary flows preferentially into a plurality of second discrete channels of a riffler assembly.
 2. The method of balancing coal flow, without disturbing an existing primary air flow, in pulverized coal boiler systems with splitter junctions having a single inlet coal pipe and a plurality of outlet coal pipes according to claim 1, wherein the positions of said pluralities of first stage and second stage flow control elements are adjusted in order to further refine/enhance the balancing effect.
 3. The method of balancing coal flow, without disturbing an existing primary air flow, in pulverized coal boiler systems with splitter junctions having a single inlet coal pipe and a plurality of outlet coal pipes according to claim 2, wherein the positions of said pluralities of first stage and second stage flow control elements are adjusted “on-line”, or in other words, while the boiler system is in operation to further refine/enhance the balancing effect.
 4. In combination with a slotted plate riffler having flow channels for directing coal flow and balancing coal flow rates among a plurality of outlet pipes from a splitter junction in a pulverized coal boiler system, a flow control assembly including a plurality of flow control elements each positioned upstream of a corresponding flow channel in said riffler for creating a particle wake and thereby preferentially directing coal flow to one of said plurality of outlet pipes from the splitter junction, said plurality of flow control elements of the flow control assembly each further comprising a streamlined shape including a rounded convex edge leading to straight tapered sides.
 5. The combination slotted plate riffler and flow control assembly according to claim 4, wherein said slotted plate riffler further comprises an orifice in each of said plurality of outlet pipes for balancing primary air flow rates.
 6. The combination slotted plate riffler and flow control assembly according to claim 4, wherein the straight tapered sides of said plurality of flow control elements each further comprise a roughened surface for promoting turbulent boundary layers.
 7. The combination slotted plate riffler and flow control assembly according to claim 4, wherein said plurality of flow control elements are mounted on means to adjust the positions of said flow control elements relative to said riffler flow channels.
 8. A system for balancing pulverized coal flow, without disturbing primary air flow in pulverized coal boiler systems of the type having a splitter junction with a single inlet coal pipe and a plurality of outlet coal pipes, said balancing system comprising: a plurality of first stage flow control elements located upstream of said splitter junction for converting a combined coal/primary air flow into a plurality of substantially equal secondary stage air and coal flows; a plurality of discrete first channels for intake of the plurality of respective secondary stage coal and air flows; a plurality of second stage flow control elements located within said plurality of discrete first channels for converting said plurality of secondary stage air and coal flows into a plurality of approximately equal, third stage air and coal flows; and a plurality of discrete second channels located downstream of said plurality of second stage flow control elements for intake of the plurality of third stage air and coal flows.
 9. The system for balancing coal flow according to claim 8, wherein said pluralities of first stage and second stage flow control elements each further comprise a streamlined shape including a rounded convex edge leading to straight tapered sides.
 10. The system for balancing coal flow according to claim 9, wherein the straight tapered sides of said pluralities of first stage and second stage flow control elements each further comprise a roughened surface for promoting turbulent boundary layers.
 11. The system for balancing coal flow according to claim 8, further comprising a means to adjust the positions of said pluralities of first stage and second stage flow control elements.
 12. The system for balancing coal according to claim 11, further comprising a means to adjust the positions of said pluralities of first stage and second stage flow control elements “on-line”, or in other words, while the boiler system is in operation. 